Frequently Asked Questions

Microfluidic devices precisely manipulate tiny volumes of fluids — ranging from microliters to picoliters — within microscopic channels just tens to hundreds of micrometers wide. These miniature labs-on-a-chip are transforming biological, chemical, and medical workflows, powering breakthroughs in diagnostics, drug development, and beyond

Common materials include:

• Polydimethylsiloxane (PDMS) – popular for prototyping.

• Glass – excellent optical properties and chemical resistance.

• Thermoplastics (e.g., PMMA, COC, PC) – ideal for mass production.

• Paper – used in low-cost diagnostics.

Microfluidic devices are used in pharmaceuticals for drug screening and delivery, in chemical manufacturing for precise reactions, in environmental monitoring for pollutant detection, and in biotechnology for cell analysis and DNA testing. They also support food safety and inkjet printing technologies.

Microfluidic devices are used in medicine for rapid diagnostics, drug delivery, DNA amplification, and disease modeling. They power lab-on-a-chip systems, point-of-care testing, organ-on-a-chip platforms, and biosensors — enabling faster, more accurate, and cost-effective healthcare solution

Absolutely. We offer full customization of channel layouts, materials, detection features, and integration with sensors. Contact us with your specifications.m dolor sit amet, consectetur adipiscing elit. In eget bibendum libero. Etiam id velit at enim porttitor facilisis. Vivamus tincidunt lectus at risus pharetra ultrices. In tincidunt turpis at odio dapibus maximus.

Some devices can be cleaned and reused, especially those made from glass or certain plastics. For clinical or high-sensitivity applications, we recommend single-use formats to ensure contamination-free results.

Degas your fluids before use, fill channels slowly, and use our optional bubble traps to ensure smooth and uninterrupted flow

Microfluidics faces challenges like precise fluid control at tiny scales, material compatibility, cross-contamination, thermal sensitivity, and scalability for mass production. Designing reliable, cost-effective devices also requires interdisciplinary expertise in fluid dynamics, materials science, and electronics